KR20060022417A - Laser scanning unit capable of correcting a curvature of field - Google Patents

Abstract

The present invention discloses an optical scanning device capable of improving scan line curvature on an upper surface generated when light is incident at a predetermined angle in the sub-scanning direction. Gwangju optical device according to one type of the present invention, a light source for generating light; An optical unit scanning the light generated by the light source to form an image to be scanned; A housing surrounding the light source and the optical unit; An optically transparent cover glass installed on a housing surface opposite to the scanning surface so that the light emitted from the optical unit can pass through the housing and enter the scanning surface; A cover glass holder for clamping both ends of the cover glass; And a fixing member for fixing the cover glass holder at a predetermined position inside the housing, wherein each fixing member at both ends of the cover glass is capable of independently changing position.

Optical scanning device, Scanning line curve, Anamorphic, Laser printer, Corrective lens, Cover glass, Photosensitive drum

Description

Laser scanning unit capable of correcting a curvature of field

1 schematically shows the structure of a typical optical scanning device.

Figure 2 schematically shows the structure of a typical tandem optical scanning device.

3 schematically shows the structure of an optical scanning device including a housing and a cover glass.

4 is a plan view showing the cover glass structure of the optical scanning device according to the present invention.

5A to 5C show an operating state of the cover glass according to the present invention.

6 shows a rotation operation of the cover glass according to the present invention.

7 shows a structure for rotating the cover glass according to the present invention.

※ Explanation of code about main part of drawing ※

40 ..... Optical scanning device housing 41 ..... Fixed member

42 ..... Cover glass holder 43 ..... Cover glass support boss

45 ..... Cover glass 46 ..... Cover glass rotating member

47 ..... hole 48 ..... shaft

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical scanning device with improved scanning line curvature, and more particularly, to an optical scanning device capable of improving scanning line curvature on an upper surface generated when light is incident at a predetermined angle in the sub-scanning direction. will be.

Background Art In general, a laser printer is a printing apparatus that forms an image while scanning laser light emitted from a laser diode on a photosensitive member, and reproduces an image image by transferring a latent image formed on the photosensitive member onto a medium such as paper. Gwangju presidential device is an image forming apparatus that generates a laser light in such a laser printer to form an image on a photosensitive member. Figure 1 schematically shows a typical Gwangju presidential device. As shown in FIG. 1, in general, the optical scanning device is largely divided into a light source 11, a collimating lens 12, a cylinder lens 13, a polygon mirror 20, a scanning lens 30, and a scanning line curvature correcting lens 50. ) And a photosensitive drum 60. The light beam emitted from the light source 11, such as a laser diode, is converted into a parallel beam with respect to the optical axis by the collimating lens 12. The parallel beam passes through the cylinder lens 13 and converges in the sub-scanning direction, thereby becoming linear light in a horizontal direction with respect to the sub-scanning direction. Thereafter, the horizontal linear light is moved at a constant velocity in the main scanning direction (ie, the horizontal direction of the paper) by the polygon mirror 20 rotating at a high speed while the scanning lens 30 and the correction lens 50 Through the photosensitive drum 60. Here, the scanning lens 30 has a constant refractive index with respect to the optical axis, and functions to focus on the photosensitive drum 60 by polarizing light having a constant velocity reflected by the polygon mirror 20 in the main scanning direction.

In the optical scanning device having the above configuration, the light beam passing through the scanning lens 30 should be scanned on the scan surface in a straight line along the main scanning direction. However, due to aberration of the scanning lens 30, the light beam is deviated by several to several tens of micrometers in the sub-scanning direction. For this reason, a problem arises in that the light beam is not scanned in a straight line along the main scanning direction of the scan surface, and the trajectory scan line of the beam spot is curved at the scan surface. Such a curved line of the scanning line is referred to as a bow, and the bow lowers the printing precision, thereby degrading the image quality.

In particular, in the case of a tandem optical scanning device used in a color laser printer or the like, scanning line curvature is a big problem. As shown in Fig. 2, the tandem type photoprecipitator simultaneously deflects several light beams into one polygon mirror and then scans the respective photosensitive drums 60a and 60b through the mirrors 40 and 41. To this end, in the case of a tandem type optical scanning device, a light beam is obliquely incident on the polygon mirror in the sub-scanning direction. However, when the light beam is incident on the polygon mirror obliquely in the sub-scanning direction, scan line curvature is more likely to occur. Moreover, since the scanning line curvature on each photosensitive drum is formed differently, color reproducibility greatly decreases in the case of a color laser printer.

In order to suppress the scan line curvature causing such a problem, conventionally, two scan lenses 31 and 32 and one scan line curvature correcting lens 50 are used. Here, the scan line curvature correcting lens 50 is for correcting the scan line curvature without changing the power distribution in the main scanning direction, and one surface of the correcting lens 50 has an anamorphic aspheric shape. However, such a configuration results in an increase in the number of parts and an increase in manufacturing and assembly costs. Furthermore, since the correction lens 50 is an anamorphic aspherical surface having a shape that is very long in the longitudinal direction as compared with the thickness direction, it is inevitably manufactured as a plastic injection lens. However, with plastic injection lenses it is very difficult to achieve the desired shape precision. Therefore, when the correction lens 50 is employed, theoretical design performance may be realized, but problems such as increase in the number of parts, weight and volume, difficulty in manufacturing parts, and increase in manufacturing and assembly costs Occurs.

The present invention is directed to improving the above-mentioned conventional problem. Accordingly, it is an object of the present invention to provide a optical scanning value which can correct the scanning line curvature caused by the light incident from the light source to the polygon mirror at a predetermined angle with respect to the sub-scanning direction without the correction lens.

Gwangju jangchi according to one type of the present invention for achieving the above object, a light source for generating light; An optical unit scanning the light generated by the light source to form an image to be scanned; A housing surrounding the light source and the optical unit; An optically transparent cover glass installed on a housing surface opposite to the scanning surface so that the light emitted from the optical unit can pass through the housing and enter the scanning surface; A cover glass holder for clamping both ends of the cover glass; And a fixing member for fixing the cover glass holder at a predetermined position in the housing, wherein each fixing member at both ends of the cover glass is capable of independently changing position.

In addition, according to the present invention, Gwangju Sasang, characterized in that it further comprises a support boss for fixing and supporting the central portion of the cover glass on the basis of the main scanning direction.

In addition, the optical photonic device according to the present invention further includes a rotating member for rotating the cover glass so that the light passing through the cover glass can be deflected in the sub-scanning direction. In this case, the rotating member is positioned between the cover glass holder and the fixing member, and the cover glass holder and the fixing member are coupled to each other through two shafts passing through the rotating member, so that the rotation of the rotating member is performed on the shaft. It is transmitted to the cover glass holder through. On the other hand, the opening formed in the rotating member so that the shaft can penetrate, characterized in that the cover glass holder and the fixing member is in the form of a long hole to move relative to the rotating member.

Hereinafter, with reference to the accompanying drawings, the configuration and operation of the optical scanning device according to an embodiment of the present invention will be described in detail.

FIG. 3 schematically shows the structure of an optical scanning device including a housing and a cover glass. As shown in FIG. 3, in general, the optical unit of the optical scanning device is installed in a separate housing 40 to prevent contamination due to dust generated inside the printer. That is, the light source 11, the collimating lens 12, the cylinder lens 13, the polygon mirror 20, the scanning lens 30, and the like are installed in the housing 40 to be protected from external dust and the like. In this case, in order for the light emitted from the optical unit to be incident on the scan surface such as the photosensitive drum 60, the light must be able to pass through the housing 40. To this end, generally, a transparent cover glass 45 is provided on one surface of the housing 40 facing the surface to be scanned.

A feature of the present invention is that instead of using a separate correction lens for correcting the scan line curvature, the scan line curvature is corrected by using the cover glass 45 which is a component already present in the general optical scanning apparatus. That is, the cover glass 45, which has been conventionally used in a flat state, is tilted or bent at a predetermined angle so as to simultaneously perform the function of the correction lens that corrects the scan line curvature.

Figure 4 is a plan view showing a cover glass structure of the optical scanning device according to the present invention for this purpose. As shown in FIG. 4, the optical fiber sticking device according to the present invention includes a cover glass holder 42 for clamping both ends of the cover glass 45 and a predetermined position of the cover glass holder 42 in the housing 40. And a rotating member 46 for rotating the cover glass 45 so that the light passing through the fixing member 41 and the cover glass 45 are deflected in the sub-scanning direction. The cover glass holder 42 and the fixing member 41 are coupled to each other through two shafts 48 passing through the rotating member 46 between the cover glass holder 42 and the fixing member 41. have.

At this time, each fixing member 41 at both ends of the cover glass 45, as indicated by the arrow in Figure 4, can be independently changed position. Since the fixing member 41 is coupled to the cover glass holder 42 through the shaft 48, the respective fixing members 41 at both ends of the cover glass 45 are placed at an arbitrary position in the housing 40. By providing it, the cover glass 45 can be bent at an arbitrary angle.

5A to 5C show the bending state of the cover glass 45 according to the positional change of the fixing member 41. First, as shown in FIGS. 5A and 5B, both fixing members 41 may move in the same direction. Then, since the center of the cover glass 45 is fixed by the cover glass support boss 43 with respect to the main scanning direction, both ends of the cover glass 45 move in the same direction. Therefore, one side becomes convex and the other side becomes concave while the cover glass 45 is bent bow-shaped. At this time, the convex surface of the cover glass 45 may face the scanning lens 30 or the photosensitive drum 60 depending on the moving direction of the fixing member 41. On the other hand, as shown in Figure 5c, the fixing member 41 on both sides may move in opposite directions to each other. Then, both ends of the cover glass 45 are bent in opposite directions. In this way, since the bending state of the cover glass 45 may vary depending on the position of the fixing member 41, it is possible to bend the cover glass 45 appropriately according to the degree of curvature of the scanning line of each optical scanning device.

On the other hand, Figure 6 shows a rotation operation of the cover glass 45 according to the present invention. The rotating member 46 described above is to allow the light passing through the cover glass 45 to be deflected in the sub-scanning direction. As described above, the scan line curvature is a phenomenon in which light deviates from several to several tens of micrometers in the sub-scanning direction. Therefore, by appropriately rotating the cover glass 45 in accordance with the degree of scanning line curvature, if the light passing through the cover glass 45 is deflected in the sub-scanning direction, the scanning line curvature can be corrected. In particular, when the cover glass 45 is rotated through the rotating member 46 and the cover glass 45 is bent through the fixing member 41, the light passing through the cover glass 45 is deflected in the sub-scanning direction. Since the degree of change is gradually changed along the main scanning direction, the scanning line curvature can be corrected in the entire optical scanning area.

FIG. 7 is a side view showing the rotating member 46 for rotating the cover glass 45. As shown in FIG. As shown in FIG. 7, two shafts 48 connected to the cover glass holder 42 and the fixing member 41 penetrate the rotating member 46. Accordingly, when the rotating member 46 rotates, the rotation of the rotating member 46 is transmitted to the cover glass holder 42 through the two shafts 48, and thus the cover glass 45 may rotate. . In this case, the opening formed in the rotating member 46 to allow the shaft 48 to penetrate is in the form of an elongated long hole 47 to one side, as shown in FIG. 7. Since the long hole 47 is formed in the rotating member 46 as described above, the shaft 48 can move within the range of the long hole 47. As a result, the cover glass holder 42 and the fixing member 41 are movable relative to the rotating member 46, and the bending of the cover glass 45 as shown in FIGS. 5A to 5C is reduced. Become possible Therefore, the distance that can adjust the bending of the cover glass 45 through the fixing member 41 is limited to the size of the long hole 47.

In such a configuration, after appropriately adjusting the position of the fixing member 41 and the rotation angle of the rotating member 46 in accordance with the scan line curvature of each optical scanning device, for example, the fixing member 41 using a screw or the like. ) And the position of the rotating member 46 is fixed so that it no longer moves. In this way, the scanning line curvature can be correctly corrected for each optical scanning device individually using the existing cover glass.

As described above, in the conventional case, the problem of curvature of the scan line was improved by separately adding a corrected lens, which is difficult to manufacture, in the optical scanning device. This can easily correct the scan line curvature. Therefore, no additional parts are required, thereby simplifying the assembly process and reducing the manufacturing cost of the optical scanning device.

Furthermore, since the scanning line curvature of the optical scanning device is conventionally corrected through a uniformly manufactured correction lens, the imaging quality may be different for each optical scanning device, but according to the present invention, individual adjustment is possible for each optical scanning device. Therefore, uniform imaging quality can be guaranteed for all optical scanning devices.

Claims (5)

An optical scanning device which deflects a plurality of light beams into a single polygon mirror to form an image on a photosensitive drum surface, the optical scanning device correcting scan line curvature through rotation or bending of a cover glass. The method of claim 1, wherein the photonic device is: A light source for generating light; An optical unit scanning the light generated by the light source to form an image to be scanned; A housing surrounding the light source and the optical unit; An optically transparent cover glass installed on a housing surface opposite to the scanning surface so that the light emitted from the optical unit can pass through the housing and enter the scanning surface; A cover glass holder for clamping both ends of the cover glass; And And a fixing member for fixing the cover glass holder at a predetermined position inside the housing, wherein each fixing member at both ends of the cover glass is capable of independently changing position. The method of claim 2, A support boss for fixing and supporting a central portion of the cover glass based on a main scanning direction; And And a rotating member which rotates the cover glass so that light passing through the cover glass is deflected in the sub-scanning direction. The method of claim 3, wherein The rotating member is positioned between the cover glass holder and the fixing member, and the cover glass holder and the fixing member are coupled to each other through two shafts passing through the rotating member, so that the rotation of the rotating member is transmitted through the shaft. Optical scanning device characterized in that the transfer to the cover glass holder. The method of claim 4, wherein And an opening formed in the rotating member to allow the shaft to pass therethrough, wherein the cover glass holder and the fixing member are in the form of a long hole so that the cover glass holder and the fixing member can be moved relative to the rotating member.

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